JP3247120B2 - Method for determining transmission quality of home traffic connection in mobile radiotelephone system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for determining the transmission quality of a home traffic connection in a mobile radiotelephone system, said mobile radiotelephone system comprising two-way radio channels, each of which is desired by one another. A home traffic connection established between a base station and a subscriber mobile station using one indicated radio channel, wherein the indicated radio channel Can be used as a traffic connection in the mobile radio telephone system by other subscribers, so that the radio signal tends to interfere with the radio signal of the home traffic connection.

[0002]

2. Description of the Related Art In a cell-divided mobile radiotelephone system, the geographical area of the system is divided into cells, which are often grouped into large groups called clusters. Each cell is assigned a number of carrier frequencies based on a frequency plan, so that cells adjacent to each other do not interfere with each other and that a carrier frequency pattern can be formed within the group. . Each cell has a base station, and a single base station can serve several cells. At this time, the carrier frequency pattern is repeated in each group. This type of mobile radiotelephone system is called CMS88, or Cellular Mo.
bile Telephone System, Eri
cssonTelecom, 1988, Chapter
6 is detailed.

In an adaptive mobile radio telephone system,
Each base station can transmit on all carrier frequencies, and channels are assigned to mobile stations after the degree of interference of different carrier frequencies has been determined. When the channels are assigned, a changing geographical pattern of carrier frequencies assigned so that one connection does not disturb the other connection is formed. Channel assignment is usually performed using a control channel having a carrier frequency, and traffic signals are transmitted over traffic channels on other carrier frequencies. When the number of carrier frequencies is limited, it is very difficult to avoid interference between separate connections using one and the same carrier frequency. This difficulty is
Above all, the mobile station is liable to give a disturbance effect of varying strength when moving. Various methods can be used for measuring the quality of the connection, for example, the aforementioned reference C.
S described in MS88, Chapter 1:10
A method using an AT (audible monitoring sound) has been proposed.
The base station transmits a sound having a modulation frequency above the audible range with the desired carrier frequency. This sound is received by the mobile station and transmitted back to the base station. The base station
By comparing the transmitted sound with the transmitted sound, the degree of interference experienced by the selected carrier frequency can be determined. For digital transmission systems, the bit error rate BER may be used as a measure of interference.
However, both of these methods have the disadvantage that they only provide an indirect measure of how the carrier frequency from the jamming connection affects the home connection.

[0004] Christer Gustavsson
By Royal Institute of Tec
hnology (Kungl. Tekniska H)
oegskolan), "Si
mullingav adaptive Kanal
val "(simulation of adaptive channel selection),
Ericsson Radio Systems A
B, 1987, for example, describes a method for reducing the number of blocked calls when changing the base station. Although base stations generally have fixedly assigned channels, they also have a small number of adaptive channels. The base station and the mobile station measure the signal strength in the call channel of the system and use these measures as a measure of the signal strength of the traffic channels to which they can be connected.
The mobile station and the base station also measure the signal strength of the traffic channel between the external mobile station and the base station. These traffic channels interfere with the connection to be established. A traffic channel is selected in which the signal strength of the disturbance is smaller than the signal strength of the call channel. Although this method allows the transmission quality of the traffic connection to be fully assessed and allows the proper selection of the traffic channel, it does not directly measure the signal strength of the selected traffic channel, which is disadvantageous. This method also does not provide the possibility of continuously measuring the transmission quality of the established home traffic connection. A similar transmission quality determination method has been proposed for European mobile telephone systems. This method is based on ETSI / GSM05.08,
Version 3.5.0, Chapter 3.

[0005]

SUMMARY OF THE INVENTION The method of the present invention aims to avoid the aforementioned disadvantages associated with the known art.

[0006]

According to the present invention, the signal strength of the carrier frequency of the home traffic connection and the signal strength of the carrier frequency of the jamming traffic connection are also reduced within the time interval in which the carrier frequency of the home connection is stopped. It is based on the principle of measurement. The invention has the features described in the claims.

[0007]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 schematically illustrates the geographical division of a cellular mobile radiotelephone system. Cell 1 having base station BS1 is included in cell group 3. The mobile telephone system is assigned a frequency band divided into several channels, for example 400 separate channels.
The mobile system has a fixed frequency plan and each cell in group 3 may make calls to fewer channels, eg, 20 channels in each cell. 400 channels are in cell group 3,
Any one channel with a fixed carrier frequency pair is distributed such that it exists only once. This prevents interference between channels. The cell 2 having the base station BS2 belongs to an adjacent cell group 4, and in this group, paging to 400 channels is possible as well. Base station B
S2 can make calls to the same channels as base station BS1, and these base stations are separated as far as possible in order to avoid interference as much as possible. A detailed description of cell division and frequency planning is given in the above referenced references CMS88, Chapter 6. FIG. 2 shows a base station BS1 with mobile stations MS1 and MS3 in cell 1 and mobile stations MS2 and M3 in cell 2.
And a base station BS2 having S4. The base station BS1 has a traffic connection with the mobile station MS1 over a traffic channel K1, which includes an outgoing channel FVC1 from the base station and an incoming channel RVC1 to the base station. The mobile station MS3 establishes a traffic connection to the base station BS1 via a control channel K3 having an outgoing control channel FOCC and an incoming control channel RECC.
The base station BS2 has a traffic connection with the mobile station MS2 by the channel K1 and with the mobile station MS4 by the channel K2, the channel K2 being the outgoing channel FVC2.
And the incoming channel RVC2. These channels are in the 800 MHz band and the carrier frequency difference between the outgoing and incoming channels is 45 MHz for all traffic and control channels. The frequency difference between two adjacent channels is 30 KHz.

As described above in connection with FIG. 1, base station B
The distance between S1 and BS2 is large, but nevertheless channel K1 in cell 1 is
There is some danger of being disturbed by interference from It is an object of the present invention to provide a method for measuring and determining the transmission quality of a home traffic connection over a channel K1 between a base station BS1 and a mobile station MS1. More specifically, this transmission quality is defined as C, where the magnitude of the signal strength of the carrier frequency of the channel K1 between the base station BS1 and the mobile station MS1 is C, and the connection between the base station BS1 and the mobile station MS1 is stopped. Assuming that the magnitude of the combined interference signal strength of the carrier frequency in the channel K1 at the time of the interference is I, the quotient C / I is determined. In the case shown, this jamming signal strength originates from the connection between the base station BS2 and the mobile station MS2, but other connections (not shown) by the channel K1 also contribute to this jamming signal strength. sell.

FIG. 2 shows a disturbance signal FI traveling from the base station BS2 to the mobile station MS1 and a disturbance signal RI traveling from the mobile station MS2 to the base station BS1. The transmission quality is determined as follows, assuming that only FI and RI are disturbing signals. The mobile station MS1 has a combined signal strength C + I of the outgoing channel FVC1 from the base stations BS1 and BS2.
Is measured. Outgoing channel FV from home base station BS1
When the carrier frequency of C1 is stopped, the mobile station MS1
Measures the intensity I of the jamming signal FI. At this time, the transmission quality is calculated as (C + I) / I-1 = C / I.
Base station BS1 measures the combined signal strength of incoming channel RVC1 from mobile stations MS1 and MS2 in a corresponding manner. When the carrier frequency of the incoming signal RVC1 from the mobile station MS1 is stopped, the base station BS1 transmits the interference signal RI
Is measured. In the present invention, only one base station or only one mobile station measures the signal strength and C
The result obtained as / I is exchanged between the stations.

In the case of the method described above, there is a problem in the measurement of the signal strength I of the carrier frequency in the interfering signal, represented in the example shown by the signals FI and RI, respectively. This measurement must be made when the carrier frequency in the home traffic connection is stopped, and in one embodiment, this problem is solved as follows. To conserve battery power, the transmitter, usually mobile station MS1, is equipped with a device for stopping the carrier frequency. This occurs during time intervals when the modulated signal is not being sent to the transmitter. The subscriber is only listening and no information on the carrier frequency of channel RVC1 has been transmitted to base station BS1. The base station BS1
During these periods of silence, the intensity I of the disturbing signal RI is measured. Devices used to stop the carrier frequency are well known to those skilled in the art and will not be described in detail here. The receiver, base station BS1,
By listening to the aforementioned SAT signal, it can be confirmed that only the interference signal RI has been measured. If the carrier frequency of the mobile station is stopped, the SAT signal transmitted from the base station is not transmitted and returned. This monitoring signal is transmitted to the frequency sharing mobile radio telephone system, that is, F
Occurs only in DMA systems. Normal D
A corresponding supervisory signal, called a VCC signal (Digital Confirmation Color Code), is used in a time division wireless system. In a time division system, the base station is a DVC
By listening to the C signal in a similar manner, it is possible to determine when the carrier frequency of the mobile station MS1 has been stopped.

In a time-division mobile telephone system, the interference signal strength I can be measured in the following manner. Each carrier frequency has a number of time slots, such as T in the exemplary time slot shown in FIG.
It is divided into S1, TS2 and TS3. Traffic is present in time slots TS1 and TS3 as shown by curve A in the figure, where C represents the signal strength at the carrier frequency and T represents time. Information about ongoing traffic is stored in base station BS1. The base station measures the strength of the jamming signal RI at times T1, T2, T3, T4 during the duration of the silence time slot TS2. The interfering signal RI is also TS11, TS1
2, three time slots TS1, TS2, TS3.
Not synchronized with. However, the silence time slot TS
There is some correlation between the jamming at 2 and the jamming at traffic time slots TS1 and TS3. As shown, the measurement at the repetition time points gives a measure of the strength of the jamming signal RI, which is also measured in the traffic time slots TS1 and T1.
It is related to S3. The corresponding measurement procedure is the base station BS
1 from the mobile station MS1, which receives the information in which the time slot is trafficked. This information is transmitted in the time slot TS1 as shown in FIG. 4 by the traffic channel. Base station B
The time slot TS1 from S1 corresponds to the synchronization sequence S
YNC, control sequence SACCH (low speed related control channel), data sequence DAT including transmitted call
A, including the aforementioned DVCC signal, and a signal sequence that includes the sequence RSVD (spare) that can be used for any desired purpose. The control sequence SACCH is used to transmit the aforementioned information related to the traffic time slot to the mobile station MS1. When measuring the disturbance I outside the home time slot, it is advantageous to carry out the measurement several times, for example at times T1, T2, T3, T4 in FIG. 3, so that the calculation of the disturbance value is good. . Such measurement is particularly important when measurement is performed from the base station BS1, because interference occurs from cells around the mobile station. Since the mobile stations are irregularly distributed in the cell areas and mobile, the resulting interference measurements are advantageously statistically processed.

The signal sequence from the base station BS1 shown in FIG. 4 gives the mobile station MS1 another possibility of measuring the disturbance I. The base station BS1 can interrupt the transmission of its carrier during the sequence RSVD in one time slot TS1, and the mobile station MS1 can measure the disturbance I during this sequence. The base station BS1 prepares for the mobile station to measure the interference since the carrier frequency from the home base station has actually been stopped for this mobile station during the sequence RSVD in the previous time slot TS1. To send a message. The mobile station also has the signal sequence RSV
The signal strength is measured continuously during D, and then R
It is possible to receive a message that the carrier frequency in the SVD has actually stopped for the duration of the previous time slot.

Another example of how disturbance I can be measured is described below. The mobile station or base station can interrupt the carrier frequency throughout the time slot, even if the information was normally to be transmitted in that time slot. Interference signal strength I
Is measured by the receiving station during this time slot.
In this case, a message is exchanged between the base station and the mobile station, so that the receiving station is informed that the carrier frequency of the transmitting station has been stopped. This message may be sent on the signal SACCH of FIG. In future European mobile telephone systems GSM, there is space in the signal sequence for the mobile station to instruct the base station to stop its carrier frequency. The disadvantage of this method is that the information that had to be exchanged between the stations during the halted time slot is lost and the bit error rate increases.

The method described above enables the determination of the signal quality of a home traffic connection by measuring and calculating the quotient C / I. This value is an important measurement value because, for example, it is possible for the mobile station to determine whether a handover, that is, a change from one channel to another channel, is required. This method has the advantage that it is based in part on a direct measurement of the signal strength C of the home carrier frequency and partly of the signal strength I of the interfering signal. The C / I value used in the present invention is not a substitute for other measures of transmission quality, for example the bit error rate, but complements those measures. This situation is clarified by the following example.

The total disturbance in the channel FVC1 to the mobile station MS1 shown in FIG. 2 is constituted, inter alia, by the aforementioned disturbance I, noise and multipath propagation. Multipath propagation may be reached from the base station BS1 to the mobile station MS1, in part by direct signals as shown in FIG. 2 and by signals reflected from buildings, surrounding hills, etc. Occur. The reflected signal is delayed with respect to the direct signal, and multipath propagation increases the bit error rate. When the signal strength C is large enough, the high bit error rate is due to strong jamming I or significant multipath propagation. To reduce the bit error rate, the mobile station MS
1 changes to a new channel from the home base station BS1, or a new base station, such as the base station BS in FIG.
3 can be changed. In this case, an appropriate selection can be made using the C / I values of the present invention. If this value is large, a large bit error rate is most likely due to multipath propagation. Changing the channel to the home base station does not change the signal propagation conditions, so the bit error rate should not be affected. The best choice in this case is to switch to a new base station. On the other hand, if
If the C / I value is small, a large bit error rate
Is strongest, which means that changing the channel with the home base station BS1 is the best choice for reducing the bit error rate. In the case of a time division system, the jamming I, and thus the bit error rate, can be reduced by switching to a new time slot at the same carrier frequency.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of cells and cell groups of a mobile telephone system.

FIG. 2 is a schematic diagram of a signal path and interference between a base station and a mobile station.

FIG. 3 is a diagram of time slots and signal strength in a time division mobile telephone system.

FIG. 4 is a signal sequence diagram of a time slot.

[Explanation of symbols]

 BS1 Base station BS2 Base station MS1 Mobile station MS2 Mobile station K1 Traffic channel K2 Traffic channel TS1 Time slot TS2 Time slot TS3 Time slot RSVD Reserved sequence C Signal strength of carrier frequency T Time

Continuation of the front page (56) References JP-A-63-177629 (JP, A) JP-A-64-12626 (JP, A) JP-A-58-146154 (JP, A) JP-A-58-133060 (JP) , A) JP-A-60-261233 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (1)

(57) [Claims] 1. A method for determining transmission quality of a home traffic connection in a mobile radiotelephone system, wherein the mobile radiotelephone system includes two-way radio channels, each having a desired frequency spacing from one another. A home traffic connection established between a first base station and a first subscriber mobile station having two carrier frequencies utilizing a first radio channel; Reused as a traffic connection between a second base station and another subscriber mobile station in the mobile radiotelephone system, so that the radio signal is transmitted to the first base station.
Measuring the combined received signal strength (C + I) of said carrier frequency in said first wireless channel during speech or data transmission at a first location, interfering with a radio signal of the home traffic connection at said base station. Measuring the signal strength (I) of the interfering carrier frequency of the first radio channel within a time interval in which the receiving carrier frequency in the home traffic connection is suspended; and Calculating the transmission quality as the quotient (C / I) of the signal strength (C) of the frequency and the signal strength (I) of the disturbing carrier frequency, and further comprising the mobile radiotelephone system having a A divided time-division radio channel, and at least one of the first base station and the first mobile station has a carrier channel Means for interrupting the transmission of a number, wherein the signal sequence transmitted during the time slot has a spare part available to the user and the first mobile station, whether at the first base station, The transmitting station, if any, interrupts transmission of its carrier frequency during the spare portion in one of the time slots, and messages regarding this interruption are exchanged in the spare portion in an adjacent time slot. The method comprising: